A MEMS resonant accelerometer includes two proof masses configured to resonate when driven with periodic signals. Each proof mass includes a resonator structure that vibrates relative to the proof mass and a dummy structure that does not resonate. When driven by a periodic drive signal, the resonator structures of the two proof masses may be used to determine the magnitude of acceleration in the direction perpendicular to the planes of the proof masses by sensing the frequency at which the resonators vibrate. For example, a differential oscillation frequency may be computed from the two sensed frequencies. The dummy structures are used to make the mass distribution of the two proof masses similar.
Legal claims defining the scope of protection, as filed with the USPTO.
1. A microelectromechanical system (MEMS) accelerometer comprising: a first teeter-totter structure, comprising: a first proof mass coupled to a substrate through a first anchor, the first proof mass having first and second mass portions having different masses and disposed at opposite sides of the first proof mass with respect to the first anchor; a first resonator structure pivotally attached to the first proof mass and configured to vibrate relative to the first proof mass; and a first dummy structure fixedly attached to the first proof mass; and a second teeter-totter structure, comprising: a second proof mass coupled to the substrate through a second anchor, the second proof mass having third and fourth mass portions having different masses and disposed at opposite sides of the second proof mass with respect to the second anchor; a second resonator structure pivotally attached to the second proof mass and configured to vibrate relative to the second proof mass; and a second dummy structure fixedly attached to the second proof mass.
2. The MEMS accelerometer of claim 1 , further comprising: a first sense electrode and a first drive electrode disposed on the substrate and in proximity to the first resonator structure of the first teeter-totter structure; and a second sense electrode and a second drive electrode disposed on the substrate and in proximity to the second resonator structure of the second teeter-totter structure.
3. The MEMS accelerometer of claim 2 , wherein a first signal from the first sense electrode and a second signal from the second sense electrode are configured to be processed in combination to determine an acceleration.
4. The MEMS accelerometer of claim 1 , wherein: the first resonator structure is at least partially surrounded by the first mass portion of the first proof mass; the first dummy structure is at least partially surrounded by the second mass portion of the first proof mass, wherein the first mass portion has a greater mass than the second mass portion.
5. The MEMS accelerometer of claim 1 , wherein: the first proof mass is elongated in a first direction; the second proof mass is elongated in the first direction; and the first anchor and the second anchor are substantially aligned along a second direction perpendicular to the first direction, forming an anchor axis.
6. The MEMS accelerometer of claim 5 , wherein: the first resonator structure is configured to vibrate about a first axis oriented along the second direction; and the second resonator structure is configured to vibrate about a second axis oriented along the second direction.
7. The MEMS accelerometer of claim 6 , wherein the first axis is on a first side of the anchor axis and the second axis is on a second side of the anchor axis.
8. The MEMS accelerometer of claim 1 , wherein: the first proof mass is coupled to the first anchor through a first plurality of tethers; and the first resonator structure is coupled to the first proof mass through a second plurality of tethers.
9. A microelectromechanical system (MEMS) device comprising: an accelerometer comprising: a first teeter-totter structure, comprising: a first proof mass coupled to a substrate through a first anchor, the first proof mass having first and second mass portions having different masses and disposed at opposite sides of the first proof mass with respect to the first anchor; a first resonator structure pivotally attached to the first proof mass and configured to resonate relative to the first proof mass; and a first dummy structure fixedly attached to the first proof mass; and a second teeter-totter structure, comprising: a second proof mass coupled to the substrate through a second anchor, the second proof mass having third and fourth mass portions having different masses and disposed at opposite sides of the second proof mass with respect to the second anchor; a second resonator structure pivotally attached to the second proof mass and configured to vibrate relative to the second proof mass; and a second dummy structure fixedly attached to the second proof mass.
10. The MEMS device of claim 9 , further comprising: a first sense electrode and a first drive electrode disposed on the substrate and in proximity to the first resonator structure of the first teeter-totter structure; and a second sense electrode and a second drive electrode disposed on the substrate and in proximity to the second resonator structure of the second teeter-totter structure.
11. The MEMS accelerometer of claim 10 , wherein a first signal from the first sense electrode and a second signal from the second sense electrode are configured to be processed in combination to determine an acceleration.
12. The MEMS device of claim 9 , wherein: the first resonator structure is at least partially surrounded by the first mass portion of the first proof mass; the first dummy structure is at least partially surrounded by the second mass portion of the first proof mass, wherein the first mass portion has a greater mass than the second mass portion.
13. The MEMS device of claim 9 , wherein: the first proof mass is elongated in a first direction; the second proof mass is elongated in the first direction; and the first anchor and the second anchor are substantially aligned along a second direction perpendicular to the first direction, forming an anchor axis.
14. The MEMS device of claim 13 , wherein: the first resonator structure is configured to vibrate about a first axis oriented along the second direction; and the second resonator structure is configured to vibrate about a second axis oriented along the second direction.
15. The MEMS device of claim 14 , wherein the first axis is on a first side of the anchor axis and the second axis is on a second side of the anchor axis.
16. The MEMS device of claim 9 , wherein: the first proof mass is coupled to the first anchor through a first plurality of tethers; and the first resonator structure is coupled to the first proof mass through a second plurality of tethers.
17. A method for sensing accelerations using a microelectromechanical system (MEMS) accelerometer, the method comprising: causing a first resonator structure to vibrate out-of-plane by vibrating about a first axis, wherein the first resonator structure is coupled to a first proof mass that includes a first dummy structure that is the same mass as the first resonator structure; causing a second resonator structure to vibrate out-of-plane by vibrating about a second axis, wherein the second resonator structure is coupled to a second proof mass that includes a second dummy structure that is the same mass as the second resonator structure; sensing a first oscillation frequency of the first resonator structure and a second oscillation frequency of the second resonator structure; and computing a differential oscillation frequency from the first and second oscillation frequencies.
18. The method of claim 17 , wherein computing the differential oscillation frequency comprises computing a difference between the first and second oscillation frequencies.
19. The method of claim 17 , further comprising obtaining information indicative of an acceleration based on the differential oscillation frequency.
20. The method of claim 17 , wherein causing the first resonator structure to resonate is performed via electrostatic attraction and repulsion.
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March 8, 2018
January 19, 2021
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